Lightning Protection Guide - 3rd updated Edition · 364 LIGHTNING PROTECTION GUIDE ... the distance required to avoid uncontrolled flashover to ad- ... based arrester or voltage-switching

Lightning and surge protection for rooftop photovoltaic systems

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LIGHTNING PROTECTION GUIDE 363www.dehn-international.com

At present, about one million PV systems are installed in Germany. Based on the fact that self-generated electricity is generally cheaper and provides a high degree of electri-cal independence from the grid, PV systems will become an integral part of electrical installations in the future. How-ever, these systems are exposed to all weather conditions and must withstand them over decades. The cables of PV systems frequently enter the building and extend over long distances until they reach the grid connec-tion point. Lightning discharges cause field-based and conducted electrical interference. This effect increases in relation with increasing cable lengths or conductor loops. Surges do not only damage the PV modules, inverters and their monitor-ing electronics, but also devices in the building installation. More importantly, production facilities of industrial build-ings may also easily be damaged and production may come to a halt.If surges are injected into systems that are far from the pow-er grid, which are also referred to as stand-alone PV systems, the operation of equipment powered by solar electricity (e.g. medical equipment, water supply) may be disrupted.

Necessity of a rooftop lightning protection system The energy released by a lightning discharge is one of the most frequent causes of fire. Therefore, personal and fire protection is of paramount importance in case of a direct lightning strike to the building. At the design stage of a PV system, it is evident whether a lightning protection system is installed on a building. Some countries’ building regulations require that public build-ings (e.g. places of public assembly, schools and hospitals) be equipped with a lightning protection system. In case of industrial or private buildings it depends on their location, type of construction and utilisation whether a lightning protection system must be installed. To this end, it must be determined whether lightning strikes are to be expected or could have severe consequences. Structures in need of pro-tection must be provided with permanently effective light-ning protection systems. According to the state of scientific and technical knowledge, the installation of PV modules does not increase the risk of a lightning strike. Therefore, the request for lightning protection measures cannot be derived directly from the mere existence of a PV system. However, substantial lightning interference may be injected into the building through these systems. Therefore, it is necessary to determine the risk resulting from a lightning strike as per IEC 62305-2 (EN 62305-2) and to take the results from this risk analysis into account when installing the PV system. For this purpose, DEHN offers the DEHNsupport Toolbox software which allows to determine the risk. A risk analysis performed by means of this software provides a re-

sult which is understood by all parties involved. The software compares the risk with the technical expenditure and provides economically optimised protection measures.Section 4.5 (Risk Management) of Supplement 5 of the German DIN EN 62305-3 standard describes that a light-ning protection system designed for class of LPS III (LPL III) meets the usual requirements for PV systems. In addi-tion, adequate lightning protection measures are listed in the German VdS 2010 guideline (Risk-oriented light-ning and surge protection) published by the German In-surance Association. This guideline also requires that LPL III and thus a lightning protection system accord-ing to class of LPS III be installed for rooftop PV systems (> 10 kWp) and that surge protection measures be taken.As a general rule, rooftop photovoltaic systems must not interfere with the existing lightning pro-tection measures.

Necessity of surge protection for PV systemsIn case of a lightning discharge, surges are induced on elec-trical conductors. Surge protective devices (SPDs) which must be installed upstream of the devices to be protected on the a.c., d.c. and data side have proven very effective in protecting electrical systems from these destructive voltage peaks. Section 9.1 of the CENELEC CLC/TS 50539-12 stand-ard (Selection and application principles – SPDs connected to photovoltaic installations) calls for the installation of surge protective devices unless a risk analysis demonstrates that SPDs are not required. According to the IEC 60364-4-44 (HD 60364-4-44) standard, surge protective devices must also be installed for buildings without external lightning protection system such as commercial and industrial build-ings, e.g. agricultural facilities. Supplement 5 of the German DIN EN 62305-3 standard provides a detailed description of the types of SPDs and their place of installation.

Cable routing of PV systemsCables must be routed in such a way that large conductor loops are avoided. This must be observed when combining the d.c. circuits to form a string and when interconnecting several strings. Moreover, data or sensor lines must not be routed over several strings and form large conductor loops with the string lines. This must also be observed when con-necting the inverter to the grid connection. For this reason, the power (d.c. and a.c.) and data lines (e.g. radiation sensor, yield monitoring) must be routed together with the equipo-tential bonding conductors along their entire route.

Earthing of PV systemsPV modules are typically fixed on metal mounting systems. The live PV components on the d.c. side feature double or reinforced insulation (comparable to the previous protective

364 LIGHTNING PROTECTION GUIDE www.dehn-international.com

Figure 9.18.3 UNI earthing clamp: A stainless steel intermediate element prevents contact corrosion, thus establish-ing reliable long-term connections between different conductor materials

insulation) as required in the IEC 60364-4-41 standard. The combination of numerous technologies on the module and inverter side (e.g. with or without galvanic isolation) results in different earthing requirements. Moreover, the insulation monitoring system integrated in the inverters is only perma-nently effective if the mounting system is connected to earth. Information on the practical implementation is provided in Supplement 5 of the German DIN EN 62305-3 standard. The metal substructure is functionally earthed if the PV system is located in the protected volume of the air-termination sys-tems and the separation distance is maintained. Section 7 of Supplement 5 requires copper conductors with a cross-section of at least 6 mm2 or equivalent for functional earthing (Figure 9.18.1). The mounting rails also have to be perma-nently interconnected by means of conductors of this cross-section. If the mounting system is directly connected to the external lightning protection system due to the fact that the separation distance s cannot be maintained, these conductors become part of the lightning equipotential bonding system. Consequently, these elements must be capable of carrying lightning currents. The minimum requirement for a lightning protection system designed for class of LPS III is a copper conductor with a cross-section of 16 mm2 or equivalent. Also in this case, the mounting rails must be permanently interconnected by means of conductors of this cross-section (Figure 9.18.2). The functional earthing / lightning equipo-tential bonding conductor should be routed in parallel and as close as possible to the d.c. and a.c. cables / lines.UNI earthing clamps (Figure 9.18.3) can be fixed on all common mounting systems. They connect, for example, cop-per conductors with a cross-section of 6 or 16 mm2 and bare round wires with a diameter from 8 to 10 mm to the mounting system in such a way that they can carry lightning currents. The integrated stainless steel (V4A) contact plate ensures corrosion protection for the aluminium mounting systems.

Separation distance s as per IEC 62305-3 (EN 62305-3)A certain separation distance s must be maintained between a lightning protection system and a PV system. It defines the distance required to avoid uncontrolled flashover to ad-jacent metal parts resulting from a lightning strike to the external lightning protection system. In the worst case, such an uncontrolled flashover can set a building on fire. In this case, damage to the PV system becomes irrelevant. Details on the calculation of the separation distance s can be found in chapter 5.6 and can be easily and quickly calculated by means of the DEHN Distance Tool software (chapter 3.3.2).

Core shadows on solar cellsThe distance between the solar generator and the external lightning protection system is absolutely essential to prevent

metal substructure

equipotential bonding at least 6 mm2 Cu

external lightning protection system; separation distance s is maintained

Figure 9.18.1 Functional earthing of the mounting systems if no external lightning protection system is installed or the separation distance is maintained (DIN EN 62305-3, Supplement 5)

metal substructure

lightning current carrying connection

equipotential bonding at least 16 mm2 Cu

external lightning protection system; separation distance s is not maintained

Figure 9.18.2 Lightning equipotential bonding for the mounting systems if the separation distance is not maintained


Ø air-termination rod x factor = distance l

10 mm 108 1.08 m

16 mm 108 1.76 m

distance l in m

core shadow

Ø air-ter-mination rod in mm

Figure 9.18.4 Distance between the module and the air-termination rod required to prevent core shadows

excessive shading. Diffuse shadows cast by, for example overhead lines, do not significantly affect the PV system and the yield. However, in case of core shadows, a dark clearly outlined shadow is cast on the surface behind an object, changing the current flowing through the PV modules. For this reason, solar cells and the associated bypass diodes must not be influenced by core shadows. This can be achieved by maintaining a sufficient distance. For example, if an air-ter-mination rod with a diameter of 10 mm shades a module, the core shadow is steadily reduced as the distance from the module increases. After 1.08 m only a diffuse shadow is cast on the module (Figure 9.18.4). Annex A of Supplement 5 of the German DIN EN 62305-3 standard provides more de-tailed information on the calculation of core shadows.

Special surge protective devices for the d.c. side of photovoltaic systemsThe U/I characteristics of photovoltaic current sources are very different from that of conventional d.c. sources: They have a non-linear characteristic (Figure 9.18.5) and cause long-term persistence of ignited arcs. This unique nature of PV current sources does not only require larger PV switches and PV fuses, but also a disconnector for the surge protec-tive device which is adapted to this unique nature and capa-ble of coping with PV currents. Supplement 5 of the German DIN EN 62305-3 standard (subsection 5.6.1, Table 1) de-scribes the selection of adequate SPDs.To facilitate the selection of type 1 SPDs, Tables 9.18.1 and 9.18.2 shown the required lightning impulse current carrying capability Iimp depending on the class of LPS, num-ber of down conductors of the external lightning protection systems as well as the SPD type (voltage-limiting varistor-based arrester or voltage-switching spark-gap-based ar-rester). SPDs which comply with the applicable EN 50539-11 standard must be used. Subsection 9.2.2.7 of CENELEC CLC/TS 50539-12 also refers to this standard.

PV generator

operating point

U [V]

I [A]ISC

conventional d.c. source

ULB = f (i)

UOCUOC

Figure 9.18.5 Source characteristic of a conventional d.c. source versus the source characteristic of a PV generator. When switching PV sources, the source characteristic of the PV generator crosses the arc voltage range

Class of LPS and max. lightning current

(10/350 µs)

Number of down conductors of the external lightning protection system

< 4 ≥ 4

Values for the voltage-limiting type 1 SPDs or type 1 combined SPDs (series connection) based on a selection of I8/20 (8/20 µs) and I10/350 (10/350 µs)

ISPD1 = ISPD2I8/20 / I10/350

ISPD3 = ISPD1 + ISPD2 = ItotalI8/20 / I10/350

ISPD1 = ISPD2I8/20 / I10/350

ISPD3 = ISPD1 + ISPD2 = ItotalI8/20 / I10/350

I or unknown 200 kA 17 / 10 34 / 20 10 / 5 20 / 10

II 150 kA 12.5 / 7.5 25 / 15 7.5 / 3.75 15 / 7.5

III and IV 100 kA 8.5 / 5 17 / 10 5 / 2.5 10 / 5

Table 9.18.1 Selection of the minimum discharge capacity of voltage-limiting type 1 SPDs (varistors) or type 1 combined SPDs (series connection of varistors and spark gaps); according to CENELEC CLC/TS 50539-12 (Table A.1)


Type 1 d.c. arrester for use in PV systems: Multipole type 1 + type 2 combined d.c. arrester, DEHNcombo YPV SCI (FM)With their integrated SCI technology, DEHNcombo YPV SCI (FM) combined arresters (Figure 9.18.6) fulfil the above mentioned requirements. In addition to the proven fault-re-sistant Y circuit, DEHNcombo YPV SCI (FM) features a three-step d.c. switching device (SCI technology). This d.c. switching device consists of a combined disconnection and short-cir-cuiting device with Thermo Dynamic Control and a fuse in the bypass path. This circuit (Figure 9.18.7) safely disconnects the arrester from the generator voltage in case of an overload and reliably extinguishes d.c. arcs. Thus, DEHNcombo YPV SCI (FM) allows to protect PV generators up to 1000 A without additional backup fuse. This arrester combines a lightning current arrester and a surge arrester in a single device, thus ensuring efficient protection of terminal equipment. With its discharge capacity Itotal of 12.5 kA (10/350 µs), it can be flex-ibly used for the highest classes of LPS. DEHNcombo YPV SCI

(FM) is available for voltages UCPV of 600 V, 1000 V and 1500 V and has a width of only 4 modules. Therefore, DEHNcombo YPV SCI (FM) is the ideal type 1 combined arrester for use in photovoltaic power supply systems.Voltage-switching spark-gap-based type 1 SPDs, for example DEHNlimit PV 1000 V2 (Figure 9.18.8), are another power-

Figure 9.18.8 DEHNlimit PV 1000 V2 spark-gap-based type 1 combined arrester

Class of LPS and max. lightning current

(10/350 µs)

Number of down conductors of the external lightning protection system

< 4 ≥ 4

Values for the voltage-switching type 1 SPDs or type 1 combined SPDs (parallel connection)

ISPD1 = ISPD2Iimp

ISPD3 = ISPD1 + ISPD2 = ItotalIimp

ISPD1 = ISPD2Iimp

ISPD3 = ISPD1 + ISPD2 = ItotalIimp

I or unknown 200 kA 25 50 12.5 25

II 150 kA 18.5 37.5 9 18

III and IV 100 kA 12.5 25 6.25 12.5

Table 9.18.2 Selection of the minimum discharge capacity of voltage-switching type 1 SPDs (spark gaps) or type 1 combined SPDs (parallel connection of varistors and spark gaps); according to CENELEC CLC/TS 50539-12 (Table A.2)

Figure 9.18.6 DEHNcombo YPV SCI type 1 combined arrester for protecting photovoltaic systems from surges and partial lightning currents

SCISCI SCISCI SCISCISCISCI

Original state

1. Activation of the

disconnector

2. Arc extinction

3. Electrical isolation

Figure 9.18.7 Switching phases of the three-step d.c. switching device integrated in DEHNguard M YPV SCI … (FM)


ful technology that allows to discharge partial lightning cur-rents in case of d.c. PV systems. Thanks to its spark gap tech-nology and a d.c. extinction circuit which allow to efficiently protect downstream electronic systems, this arrester series has an extremely high lightning current discharge capacity Itotal of 50 kA (10/350 µs) which is unique on the market.

Type 2 d.c. arrester for use in PV systems: DEHNguard M YPV SCI … (FM) and DEHNcube YPV SCI ...Reliable operation of SPDs in d.c. PV circuits is also indis-pensable when using type 2 surge protective devices. To this end, the DEHNguard M YPV SCI … (FM) and DEHNcube YPV SCI ... surge arresters also feature a fault-resistant Y protec-tive circuit and the SCI technology (Figure 9.18.9 and 9.18.10) and are also connected to PV generators up to 1000 A without additional backup fuse.

The numerous technologies combined in these arresters pre-vent damage to the surge protective device due to insula-tion faults in the PV circuit, the risk of fire of an overloaded arrester and puts the arrester in a safe electrical state with-out disrupting the operation of the PV system. Thanks to the protective circuit, the voltage-limiting characteristic of varistors can be fully used even in the d.c. circuits of PV systems. In addition, the permanently active surge protec-tive device minimises numerous small voltage peaks. Thus, the SCI technology increases the service life of the entire d.c.-side PV system.

Selection of SPDs according to the voltage protection level UpThe operating voltage on the d.c. side of PV systems dif-fers from system to system. At present, values up to 1500 V d.c. are possible. Consequently, the dielectric strength of ter-minal equipment also differs. To ensure that the PV system is reliably protected, the voltage protection level Up of the SPD must be lower than the dielectric strength of the PV system it is supposed to protect. The CENELEC CLC/TS 50539-12 standard requires that Up is at least 20 % lower than the dielectric strength of the PV system. Type 1 or type 2 SPDs must be energy-coordinated with the input of terminal equipment. If SPDs are already integrated in terminal equip-ment, coordination between the type 2 SPD and the input circuit of terminal equipment is ensured by the manufac-turer (Figure 9.18.11).

Figure 9.18.11 DEHNguard type 2 SPD integrated in the inverter for the a.c. and d.c. side

SCI SCI

Figure 9.18.9 Modular DEHNguard M YPV SCI … (FM) type 2 surge arrester with fault-resistant Y circuit and three-step d.c. switching device

Figure 9.18.10 Ready-to-install type 2 DEHNcube YPV SCI 1000 1M surge arrester


~=

PCPC

GJBGJB

MEB

DNO Distribution network operator GJB Generator junction box M Meter MEB Main earthing busbar SEB Service entrance box

SEBDNO

M M

6 mm2 Cu6 mm2 Cu

Figure 9.18.12 Building without external LPS – situation A (Supplement 5 of the DIN EN 62305-3 standard)

No. in Fig. SPD * FM = Floating remote signalling contact Part No.

d.c. input of the inverter

Per MPPT DEHNguard DG M YPV SCI 1000 FM * 952 515

For 1 MPPT DEHNcube DCU YPV SCI 1000 1M 900 910

For 2 MPPTs DEHNcube DCU YPV SCI 1000 2M 900 920

a.c. output of the inverter

TN-S system DEHNguard DG M TNS 275 FM * 952 405

Low-voltage input

TN-C system DEHNguard DG M TNC CI 275 FM * 952 309

TN-S system DEHNguard DG M TNS CI 275 FM * 952 406

TT system DEHNguard DG M TT CI 275 FM * 952 327

Data interface

Two pairs, even with different operating voltages up to 180 V

BLITZDUCTOR BXTU ML4 BD 0-180+ BXT BAS base part

920 349+ 920 300

Functional earthing

Functional equipotential bonding UNI earthing clamp 540 250


~=

GJBGJB

MEB

DNO Distribution network operator GJB Generator junction box M Meter MEB Main earthing busbar s Separation distance SEB Service entrance box

SEBDNO

M

PCPC

M

separation distance keptseparation distance kept

6 mm2 Cu6 mm2 Cu

≥ s

Figure 9.18.13 Building with external LPS and sufficient separation distance – situation B (Supplement 5 of the DIN EN 62305-3 standard)



Per MPPT DEHNguard DG M YPV SCI 1000 FM * 952 515

For 1 MPPT DEHNcube DCU YPV SCI 1000 1M 900 910

For 2 MPPTs DEHNcube DCU YPV SCI 1000 2M 900 920


TN-S system DEHNguard DG M TNS 275 FM * 952 405

Low-voltage input

TN-C system DEHNventil DV M TNC 255 FM * 951 305

TN-S system DEHNventil DV M TNS 255 FM * 951 405

TT system DEHNventil DV M TT 255 FM * 951 315

Data interface



920 349+ 920 300

Functional earthing / External lightning protection system


Air-termination systemAir-termination rod withconcrete base (8.5 kg)

101 000+ 102 075


that an additional type 2 d.c. arrester be installed on the module side if the distance between the inverter input and the PV generator exceeds 10 m.The a.c. outputs of the inverters are sufficiently protected if the distance between the PV inverters and the place of installation of the type 2 arrester at the grid connection point (low-voltage infeed) is less than 10 m. In case of greater cable lengths, an additional type 2 surge protective device, for example DEHNguard M … 275, must be installed upstream of the a.c. input of the inverter as per CENELEC CLC/TS 50539-12. Moreover, a type 2 DEHNguard M … CI 275 (FM) surge pro-tective device must be installed upstream of the meter of the low-voltage infeed. CI (Circuit Interruption) stands for a coordinated fuse integrated in the protective path of the ar-rester, allowing the arrester to be used in the a.c. circuit with-out additional backup fuse. DEHNguard M … CI 275 (FM) is available for every low-voltage system configuration (TN-C, TN-S, TT).If inverters are connected to data and sensor lines to moni-tor the yield, suitable surge protective devices are required. BLITZDUCTOR XTU, which features terminals for two pairs, for example for incoming and outgoing data lines, can be used for data systems based on RS 485.

Building with external lightning protection system and sufficient separation distance s (situation B)Figure 9.18.13 shows the surge protection concept for a PV system with external lightning protection system and sufficient separation distance s between the PV system and the external lightning protection system.The primary protection goal is to avoid damage to persons and property (building fire) resulting from a lightning strike. In this context, it is important that the PV system does not interfere with the external lightning protection system. Moreover, the PV system itself must be protected from di-rect lightning strikes. This means that the PV system must be installed in the protected volume of the external lightning protection system. This protected volume is formed by air-termination systems (e.g. air-termination rods) which prevent

direct lightning strikes to the PV modules and cables. The protective angle method (Figure 9.18.14) or rolling sphere method (Figure 9.18.15) as described in subsec-tion 5.2.2 of the IEC 62305-3 (EN 62305-3) standard may be used to determine this protected volume. A certain separation distance s must be maintained between all conductive parts of the PV system and the lightning protection system. In this context,

Application examples:

Building without external lightning protection system (situation A)Figure 9.18.12 shows the surge protection concept for a PV system installed on a building without external lightning protection system. Dangerous surges enter the PV system due to inductive coupling resulting from nearby lightning strikes or travel from the power supply system through the service entrance to the consumer’s installation. Type 2 SPDs are to be installed at the following locations:

¨ d.c. side of the modules and inverters

¨ a.c. output of the inverter

¨ Main low-voltage distribution board

¨ Wired communication interfaces

Every d.c. input (MPP) of the inverter must be protected by a type 2 surge protective device, for example DEHNguard M YPV SCI … (FM), that reliably protects the d.c. side of PV systems. The CENELEC CLC/TS 50539-12 standard requires

Figure 9.18.14 Determination of the protected volume using the protective angle method

sseparation distance

air-termi-nation rod

pro-tective angle

rolling sphere radius depending on

the class of LPS

Figure 9.18.15 Rolling sphere method versus protective angle method for determining the protected volume


core shadows must be prevented by, for example, maintain-ing a sufficient distance between the air-termination rods and the PV module. Lightning equipotential bonding is an integral part of a lightning protection system. It must be implemented for all conductive systems and lines entering the building which may carry lightning currents. This is achieved by directly con-necting all metal systems and indirectly connecting all en-ergised systems via type 1 lightning current arresters to the earth-termination system. Lightning equipotential bonding should be implemented as close as possible to the entrance point into the building to prevent partial lightning currents from entering the building. The grid connection point must be protected by a multipole spark-gap-based type 1 SPD, for example a type 1 DEHNventil M … 255 combined ar-rester. This arrester combines a lightning current arrester and a surge arrester in a single device. If the cable lengths between the arrester and the inverter are less than 10 m, sufficient protection is provided. In case of greater cable lengths, additional type 2 DEHNguard M surge protective devices must be installed upstream of the a.c. input of the inverters as per CENELEC CLC/TS 50539-12. Every d.c. input of the inverter must be protected by a type 2 PV arrester, for example DEHNcube YPV SCI … (Figure 9.18.16). This also applies to transformerless devices. If the inverters are connected to data lines, for example to monitor the yield, surge protective devices must be installed to pro-tect data transmission. For this purpose, BLITZDUCTOR XTU with actiVsense technology can be provided for lines with analogue signal and data bus systems such as RS485. It au-

Figure 9.18.16 DEHNcube YPV SCI 1000 1M type 2 arrester for protecting inverters (1 MPPT)

tomatically detects the operating voltage of the useful sig-nal and adjusts the voltage protection level to this operating voltage.

High-voltage-resistant, insulated HVI ConductorAnother possibility to maintain the separation distance s is to use high-voltage-resistant, insulated HVI Conductors which allow to maintain a separation distance s up to 0.9 m in air. HVI Conductors may directly contact the PV system downstream of the sealing end range. More detailed infor-mation on the application and installation of HVI Conduc-tors is provided in this Lightning Protection Guide or in the relevant installation instructions.

Building with external lightning protection system with insufficient separation distance s (situation C)If the roofing is made of metal or is formed by the PV sys-tem itself, the separation distance s cannot be maintained. The metal components of the PV mounting system must be connected to the external lightning protection system in such a way that they can carry lightning currents (copper conductor with a cross-section of at least 16 mm2 or equiva-lent). This means that lightning equipotential bonding must also be implemented for the PV lines entering the building from the outside (Figure 9.18.17). According to Supple-ment 5 of the German DIN EN 62305-3 standard and the CENELEC CLC/TS 50539-12 standard, d.c. lines must be pro-tected by a type 1 SPD for PV systems. For this purpose, a type 1 and type 2 DEHNcombo YPV SCI (FM) combined arrester is used. Lightning equipotential bond-ing must also be implemented in the low-voltage infeed. If the PV inverter(s) is (are) situated more than 10 m from the type 1 SPD installed at the grid connection point, an ad-ditional type 1 SPD must be installed on the a.c. side of the inverter(s) (e.g. type 1 + type 2 DEHNshield ... 255 combined arrester). Suitable surge protective devices must also be in-stalled to protect the relevant data lines for yield monitor-ing. BLITZDUCTOR XTU surge protective devices are used to protect data systems, for example based on RS 485.

PV systems with microinvertersMicroinverters require a different surge protection concept. To this end, the d.c. line of a module or a pair of modules is directly connected to the small-sized inverter. In this process, unnecessary conductor loops must be avoided. Inductive coupling into such small d.c. structures typically only has a low energetic destruction potential. The extensive cabling of a PV system with microinverters is located on the a.c. side (Figure 9.18.18). If the microinverter is directly fitted at the module, surge protective devices may only be installed on the a.c. side:


~=

MEB

SEB

M

PCPC

M

GJBGJB

DNO Distribution network operator GJB Generator junction box M Meter MEB Main earthing busbar s Separation distance SEB Service entrance box

DNO

16 mm2 Cu16 mm2 Cu

separation distance not kept

separation distance not kept

< s

Figure 9.18.17 Building with external LPS and insufficient separation distance – situation C (Supplement 5 of the DIN EN 62305-3 standard)



Per MPPT DEHNcombo DCB YPV SCI 1000 FM * 900 066


TN-S system DEHNshield DSH TNS 255 941 400

Low-voltage input

TN-C system DEHNventil DV M TNC 255 FM * 951 305

TN-S system DEHNventil DV M TNS 255 FM * 951 405

TT system DEHNventil DV M TT 255 FM * 951 315

Data interface



920 349+ 920 300

Functional earthing / External lightning protection system


Air-termination systemAir-termination rod withconcrete base (8.5 kg)

101 000+ 102 075


~=

~=

~=

~=

~=

~=

a.c. cables (interconnected)

a.c.

d.c.

factory-mounted cables

a.c. box (interface to cables laid on site)

cables laid on site

a.c. power connection

¨ Buildings without external lightning protection system = type 2 DEHNguard M … 275 arresters for alternat-ing / three-phase current in close proximity to the micro-inverters and DEHNguard … 275 CI at the low-voltage infeed.

¨ Buildings with external lightning protection system and sufficient separation distance s = type 2 arresters, for example DEHNguard M … 275, in close proximity to the micro inverters and lightning current carrying type 1 ar-resters at the low-voltage infeed, for example DEHNventil M ... 255.

¨ Buildings with external lightning protection system and insufficient separation distance s = type 1 arresters, for example DEHNshield … 255, in close proximity to the

microinverters and lightning current carrying type 1 DEHNventil M ... 255 arresters at the low-voltage infeed.

Independent of particular manufacturers, microinverters fea-ture data monitoring systems. If data is modulated to the a.c. lines via the microinverters, a surge protective device (for example DEHNbox DBX KT BD) must be provided on the separate receiving units (data export / data processing). The same applies to interface connections with downstream bus systems and their voltage supply (e.g. Ethernet, ISDN).

Solar power generation systems are an integral part of to-day’s electrical systems. They should be equipped with ad-equate lightning current and surge arresters, thus ensuring long-term faultless operation of these sources of electricity.

Figure 9.18.18 Example: Building without external lightning protection system; surge protection for a microinverter located in the connection box of the on-site cables

Lightning Protection Guide - 3rd updated Edition · 364 LIGHTNING PROTECTION GUIDE ... the distance required to avoid uncontrolled flashover to ad- ... based arrester or voltage-switching

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